KR200267524Y1 - Fuel reduction heating system - Google Patents

Abstract

The present invention relates to a fuel-saving heating system, and in a general heating system including a heat exchanger block including a burner, a heating pipe, a hot water pipe, and a circulation pump, each of the heat exchanger blocks has an inlet and an outlet. And divided into a heating heat exchanger block for passing the heating fluid and a hot water heat exchanger block for passing the hot water; The flow path of the heating heat exchanger block is formed in a zigzag form to have a predetermined width and depth; The flow path of the hot water heat exchanger block is formed in a zigzag form to have a predetermined width and depth; The heating heat exchanger block and the hot water heat exchanger block is made by mutual coupling by the coupling member, the heating fluid passes through the zigzag-shaped flow path, the heat medium with a high specific heat instead of water flows into the heating fluid, the communication gas is discharged Including the exhaust heat exchanger at the end of the fuel economy can be reduced, because the double heating pipe is used to heat transfer effect is large, the heating pipe is installed on the insulating material with a seating groove to facilitate the installation of the heating pipe. It is to provide a fuel-saving heating system.

Description

Fuel-saving heating system {FUEL REDUCTION HEATING SYSTEM}

The present invention relates to a fuel-saving heating system, and in a general heating system consisting of a heat exchanger block including a burner, a heating pipe, a hot water pipe, a circulation pump, and the like, a hot water heat exchanger in which water passes through the heat exchanger block. The heat exchanger block is formed by dividing the block and the heat medium oil respectively. The heat medium oil provides a heating system applicable to a large heating load by using oil having a large specific heat, and the heat pipe is formed by a double heat conduction. The present invention relates to a fuel-saving heating system capable of efficiently heating a large heat transfer area.

Conventional heating system is to heat the water directly or indirectly with a heating device such as a burner burner to be used as hot water or indoor heating while the heated water is supplied and circulated to the hot water pipe and heating pipe.

However, such a heating system has a problem that the heat sequence of heat is limited because the circulation path of the hot water is monotonically determined by the standardized heating pipe and the heat efficiency cannot be obtained by a certain level. In addition, the water is heated by applying a constant combustion heat, the water does not increase the sensible heat above 100 ℃, there is a limit to the heating to the space having a large heating load, the use of hot water affects the temperature of the hot water for heating, etc. There was a problem.

The present invention has been devised to solve such a conventional problem, the object of the present invention is to install a heating heat exchanger block and a hot water heat exchanger block divided into partitions to increase the thermal efficiency by adjusting the temperature of the fluid to fit the heating and hot water, The use of hot water does not affect the heating temperature, and the flow path of the heating heat exchanger block circulates thermal oil such as oil having a high specific heat instead of water to provide a fuel-saving heating system for heating by increasing the heat storage effect.

In addition, the flow path of the hot water heat exchanger block and the flow path of the heating heat exchanger block are formed in a zigzag shape so that the hot water or the heat medium oil is sufficiently heated and discharged through the extended heat transfer area in the course of passing the fluid flowing into the heat exchanger block through the flow path. Therefore, to provide a fuel-saving heating system that can be heated within a predetermined time, the temperature required for heating and hot water is raised to enable heating and hot water supply.

In addition, since the heating pipe installed in the heating space is formed in double, the heat dissipation area can be enlarged to maximize the heating effect of the heating space with a large heating load, and it is easy to connect the pipe of the heating pipe with a connecting pipe. To provide a fuel-saving heating system that can be installed.

1 is a schematic view of a fuel-saving heating system according to the present invention,

2 is a cross-sectional view of a heat exchanger block of a fuel-saving heating system according to the present invention;

3 is a perspective view of a heat exchanger block of a fuel-saving heating system according to the present invention;

Figure 4a is a plan view of a heating pipe of the fuel-saving heating system according to the present invention,

Figure 4b is a longitudinal sectional view of the straight pipe of the heating pipe of Figure 4a,

5 is a cross-sectional view of the construction of the heating pipe of the fuel-saving heating system according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: heat exchanger block 2: heating piping

3: hot water pipe 4: hot water circulation pump

4 ': thermal fluid circulation pump 5, 5': insulation

6: water tank 6 ': thermal fluid tank

7: fuel tank 8: valve

9: exhaust heat exchanger 10: finishing layer

11: heating heat exchanger block 12: hot water heat exchanger block

13: auxiliary hot water heat exchanger block 14: flow path connector

15: Communication 16: Burner

17: hot water inlet 17 ': heat medium oil inlet

18: hot water outlet 18 ': heat medium oil outlet

19: coupling member 21: straight pipe

22: connector 51: seating groove

52: projection 91: cold water inlet

92: cold water outlet

In order to achieve the above object, the present invention is a general heating system consisting of a heat exchanger block, a heating pipe, a hot water pipe, a circulation pump, and the like including a burner, the heat exchanger block is formed with an inlet and an outlet, respectively. And divided into a heating heat exchanger block for passing the heating fluid and a hot water heat exchanger block for passing the hot water; The flow path of the heating heat exchanger block is formed in a zigzag form to have a predetermined width and depth; The flow path of the hot water heat exchanger block is formed in a zigzag form to have a predetermined width and depth; The heating heat exchanger block and the hot water heat exchanger block is a fuel-saving heating system, characterized in that made by mutual coupling by a coupling member.

In addition, portions other than the flow path of the heating heat exchanger block and the hot water heat exchanger block may be formed in the flow path of the heating heat exchanger block and the hot water heat exchanger block so that the hot gas or flame supplied from the combustion burner contacts or passes. The space portion is formed to have the same size as the width.

The apparatus may further include an exhaust heat exchanger for preheating the water supplied to the hot water heat exchanger block by collecting heat of the combustion gas at an end portion of the communication section through which the high temperature combustion gas is discharged through the heat exchanger block.

In addition, a separate auxiliary hot water heat exchanger block having the same width and depth as the hot water heat exchanger block and having a long flow path in order to allow a large amount of hot water to be heated to the hot water heat exchanger block attached to the heating heat exchanger block. It is possible to install at least one additionally.

Preferably, the straight pipe of the heating pipe is located around the heating water pipe of the circular cross-section in order to increase the heat transfer area, the heat dissipation tube of a circular cross section larger than the diameter of the heating water pipe is located and then press the heat dissipating tube to the outer peripheral surface of the heating water pipe In contact with it to form an oval tube; Forming one or more conductive pipes by attaching one or more conductive plates in both horizontal diameter directions of the heating water pipes to transfer the heat of the heating water pipes to the heat radiating pipes; In order to connect the straight pipes arranged in a plurality of rows in series, the ends of the straight pipes may be screwed into a flexible connection pipe to form a heating pipe.

In addition, in order to allow the straight pipe to be easily positioned at a predetermined interval and to transmit heat in one direction, a straight groove having a predetermined depth is formed on the upper surface of the heat insulating material, characterized in that the straight pipe is positioned.

An embodiment according to the present invention will be described with reference to the accompanying drawings.

1 is a schematic view of a fuel-saving heating system according to the present invention, the present invention is a combustion burner 16, a heating heat exchanger block 11, a main hot water heat exchanger block 12 and an auxiliary hot water heat exchanger block (13). A heat exchanger block 1 comprising; A fuel tank 7 for supplying fuel to the combustion burner 16; A communication unit 15 penetrating from the heat exchanger block 1 so as to discharge high-temperature combustion gas and protruding to one side; Thermal oil tank 6 'for storing thermal oil; A valve (8) for controlling the supply of heat medium oil; A heat medium oil inlet 17 'formed at one side of the heating heat exchanger block 11 and a heat medium oil outlet 18' formed at the other side; A heating pipe through which the heat medium oil flows; A heat medium oil circulation pump (4 ') circulating the heat medium oil; A water supply tank 6 in which water is stored; An exhaust heat exchanger (9) for preheating the water supplied to the hot water heat exchanger blocks (12, 13) at the distal end of the communication (15); A cold water inlet 91 formed at one side of the exhaust heat exchanger 9 and a cold water outlet 92 formed at the other side; A hot water inlet 17 formed at one side of the hot water heat exchanger blocks 12 and 13 and a hot water outlet 18 formed at the other side; Hot water pipes 3 to which hot water is supplied; It comprises a hot water circulation pump (4) for supplying the hot water.

At least one combustion burner 16 is installed at the front portion of the heat exchanger block 1 to heat the heat exchanger block 1 by combustion gas or flame, and the high temperature combustion gas generated in the heating process. Is discharged through the communication 15 formed to protrude to one side through the space (111, 121, 131) of the heat exchanger block (1).

Heat medium oil such as oil having a high specific heat flows into the heat exchanger block 11 from the heat medium oil tank 6 'through the heat medium oil inlet 17' formed at one side of the heat exchanger block 11, The shortage is replenished from the heat medium oil tank 6 '. The high temperature heat medium oil, which has received heat from the combustion burner 16 while passing through the heat exchanger block 11, is installed in the heating space through the heat medium oil outlet 18 ′ on the other side of the heat exchanger block 11. It flows into the heating pipe (2) which is being heated. The heat medium oil repeats the circulation process by the heat medium circulation pump 4 ', and supplements the amount of heat medium oil circulated by a shortage from the heat medium oil tank 6' by the valve 8. Will be adjusted.

Water in the water supply tank (6) is introduced through the cold water inlet (91) formed at one side of the exhaust heat exchanger (9) formed at the distal end of the communication (15) and the water introduced into the exhaust heat exchanger (9) The combustion burner 16 is preheated by the heat of the hot combustion gas discharged in the process of heating the heat exchanger block 1 and then discharged through the cold water outlet 92 on the other side of the exhaust heat exchanger 9. do. The cold water outlet 92 supplies the preheated water to the hot water inlet 17 formed at one side of the auxiliary hot water heat exchanger block 13, and the preheated water is mutually connected by a flow path connecting pipe 14 not shown. It is heated while passing through the connected secondary hot water heat exchanger block 13 and the main hot water heat exchanger block 12, and is discharged through the hot water outlet 18 formed at one side of the main hot water heat exchanger block 12. The hot water heated through the above process is supplied by the hot water circulation pump 4 through the hot water pipe 3.

2 is a cross-sectional view of a heat exchanger block of a fuel-saving heating system according to the present invention. The heating heat exchanger block 11 and the hot water heat exchanger block 12 embedded in the heat exchanger block 1 are formed separately, and the heating heat exchanger block 11 and the main temperature are coupled by a coupling member 19. The water heat exchanger blocks 12 are coupled to each other. In addition, an auxiliary hot water heat exchanger block 13 is added to the front end of the main hot water heat exchanger block 12 to enable abundant amount of hot water supply. In addition, the number of the auxiliary hot water heat exchanger blocks 13 may be sequentially added to the front end of the main hot water heat exchanger block 12 as necessary according to the capacity of the hot water supply. Although not shown, at least one combustion burner 16 is installed at the front portion of the heat exchanger block 1 to heat the heat exchanger block 1. Outside of the heat exchanger block 1 is formed to form a layer of a heat insulating material (5 ') having a low thermal conductivity and excellent heat resistance so that the heat applied to the heat exchanger block (1) does not flow out.

In addition, the communication gas 15 penetrating from the heat exchanger block 1 protrudes to one side, and a high temperature combustion gas generated in the process of heating the heat exchanger block 1 by the combustion burner 16 Discharged. An exhaust heat exchanger 9 is provided at the distal end of the communication 15 to preheat the water supplied to the hot water heat exchanger blocks 12 and 13 by the heat of the hot combustion gas discharged to the communication 15. By using the waste heat, the thermal efficiency of the entire heating system can be improved.

The heating heat exchanger block 11, the main hot water heat exchanger block 12, and the auxiliary hot water heat exchanger block 13 are flow paths 112, 122, and 132 through which water or heat medium oil passes, and the flow paths 112, 122, and 132. It consists of the space (111, 121, 131) formed at equal intervals so that the hot gas or flame is in contact with or pass through the same width and the same size). In addition, the flow paths 112, 122, and 132 of the heating heat exchanger block 11, the main hot water heat exchanger block 12, and the auxiliary hot water heat exchanger block 13 are in a zigzag form, so that the heat medium oil or the water The heat exchange is carried out by passing through a larger area while passing, and thus the thermal oil or the water obtains a lot of thermal energy from a hot gas or a flame, thereby increasing heating or hot water supply efficiency.

The heat medium oil inlet 17 'is formed at one side of the heating heat exchanger block 11, and the heat medium oil outlet 18' is formed at the other side. In the heating heat exchanger block 11, the heat medium oil is introduced through the heat medium oil inlet 17 ′, heated while passing through the flow path 112 of the heating heat exchanger block 11, and flows out through the heat medium oil outlet 18 ′. do. As a heat medium oil flowing in the flow path 112 of the heating heat exchanger block 11, the oil having a high specific heat is adopted, and is heated to 100 ° C. or higher to have sensible heat greater than water, so that a large heating load is required. To be applied. As the heat medium oil used in the present invention, an oil having properties such as heat and oxidation safety, excellent heat transfer ability, non-toxicity, and corrosion resistance at high temperatures is used. In addition, since the oil has a lower freezing point than water, it is possible to solve the problem of freezing the heating pipe 2 by the outdoor air in winter.

Hot water inlet 17 may be formed on one side of the main hot water heat exchanger block 12 and the auxiliary hot water heat exchanger block 13, and a hot water outlet 18 may be formed on the other side of the main hot water heat exchanger block 13, The flow path 122 of the exchanger block 12 and the flow path 132 of the auxiliary hot water heat exchanger block 13 are connected to each other by a flow path connecting pipe 14 so that the two flow paths 122 and 132 are connected to each other. The hot water inlet 17 may be formed at one side of the giga block 13, and the hot water outlet 18 may be formed at one side of the main hot water heat exchanger block 12. Since the flow path 122 of the main hot water heat exchanger block 12 and the flow path 132 of the auxiliary hot water heat exchanger block 13 are connected to the flow path connecting pipe 14, the hot water preheated by the exhaust heat exchanger 9 is It is discharged through the cold water outlet 92 formed at one side of the exhaust heat exchanger 9 and through the hot water inlet 17 at one side of the auxiliary hot water heat exchanger block 13 connected to the cold water outlet 92. Inflow is heated while passing through the flow path 132 of the auxiliary hot water heat exchanger block 13, the flow path connecting pipe 14 and the flow path 122 of the main hot water heat exchanger block 12, the main hot water heat exchanger block The hot water is discharged through the hot water outflow pipe 18 formed at the other side of 12 to supply hot water.

The spaces 111 and 121 of the heating heat exchanger block 11 and the main hot water heat exchanger block 12 are heated by the same combustion burner 16 so that heat is also generated in the main hot water heat exchanger block 12 during the heating operation. It is possible to supply a small amount of hot water that can be delivered and used in daily life without separately operating the combustion burner 16 for hot water supply. However, when a large amount of hot water needs to be supplied, hot water is supplied by operating both the combustion heat exchanger block 11 and the combustion burner 16 provided in the front portion of the auxiliary hot water heat exchanger block 13.

3 is a perspective view of a heat exchanger block of a fuel-saving heating system according to the present invention. The heating heat exchanger block 11 and the hot water heat exchanger block 12 are separately formed and then coupled by the coupling member 19. The width of the flow path 112 of the heating heat exchanger block 11 is 2-4 mm, the depth is 40-80 mm, the width of the flow path 122 of the hot water heat exchanger block 12 is 8-10 mm, depth is 40-80 mm. It is formed in the range of each. As shown in FIG. 2, when the auxiliary hot water heat exchanger block 13 is added to the front end of the main hot water heat exchanger block 12, the auxiliary hot water heat exchanger block 13 is used as the main hot water heat exchanger block 12. Although the width of the flow path 122 and the width of the flow path 132 of the auxiliary hot water heat exchanger block 13 are the same, the length of the flow path 132 of the auxiliary hot water heat exchanger block 13 is formed to be long. A greater amount of hot water is formed to heat up. When one or more hot water heat exchanger blocks 12 are added, it is also possible to form the heat exchanger block 1 by increasing the width and length of the flow path according to the amount of hot water required.

Figure 4a is a plan view of the heating pipe of the fuel-saving heating system according to the present invention. The heating pipe (2) is buried in a zigzag form at a predetermined interval so as to pass the high temperature heat medium oil to the bottom surface of the heating space, the heating pipe (2) is a plurality of rows of straight pipes 21 are connected pipe 22 The connection pipe 22 is formed of a U-shaped portion 222 and a female screw portion 221 having flexibility. Male threads 214 are formed at both ends of the straight pipe 21 arranged in a plurality of rows so as to be screwed with the female screw parts 221 formed at both ends of the connecting pipe 22 to form a heating pipe 2. do.

4B is a longitudinal cross-sectional view of the straight pipe of FIG. 4A, wherein the straight pipe 21 is a heat dissipation pipe 212 having a circular cross section larger than the diameter of the heating water pipe 211 around the heating water pipe 211 of the circular cross section in order to increase the heat transfer area. ) And then press the heat dissipation tube 212 to form an oval tube to contact the outer circumferential surface of the heating water tube 211, and the heat of the heating water tube 211 is easily transferred to the heat dissipation tube 212. The conductive plate 213 having at least one thermal conductivity excellent in both horizontal diameter directions of the heating water pipe 211 is attached so that the temperature of the high temperature heat medium oil passing through the heating water pipe 211 causes the conductive plate 213 to be transferred. To be conducted to the heat dissipation tube 212 through. In addition, the conductive plate 213 is formed on the outer circumferential surface of the heating water pipe 211 to maintain a distance from the heat dissipation pipe 212, the heating water pipe 211 is the center of the heat dissipation pipe 212 It is fixed to be located in.

5 is a cross-sectional view of a heating pipe of the fuel-saving heating system according to the present invention constructed, the heating pipe (2) is located on the heat insulating material (5) having a low thermal conductivity, such as polyurethane foam, the heating pipe ( The heat radiated in 2) is prevented from being transferred to the ground floor or the lower floor, and heat is transferred only in the direction in which the heating is required to enable efficient heating, resulting in fuel saving effect. The heating pipe (2) is located in the seating groove 51 of the heat insulating material (5) is formed regularly curved so that the straight pipe 21 is easily positioned to facilitate the construction of the heating pipe (2). In order to connect the straight pipes 21 arranged in a plurality of rows in series, the straight pipes 21 are placed in the seating grooves 51 of the heat insulating material 5, and then the straight pipes 21 and the connecting pipes shown in FIG. After connecting both ends of (22) by screwing, finish the construction of the heating pipe (2) with a finishing layer (10).

In the fuel-saving heating system according to the present invention, since the heating heat exchanger and the hot water heat exchanger are separated, it is possible to control the temperature of the heating fluid or hot water passing through the heat exchanger according to the heating and hot water use, and the use of hot water affects the heating. It does not give a heating fluid or hot water to pass through the zigzag flow path to provide a large heat exchange area, and is heated and discharged within a certain time, so that the heating and hot water efficiency can be increased, resulting in a fuel saving effect. Since heat medium oil, which has a high specific heat, is used as a fluid, it is suitable for heating a place having a large heating load, and the heat medium oil has a low freezing point, which solves the problem of freezing the heating pipe by outdoor air in winter. .

In addition, by further including an exhaust heat exchanger at the distal end of the communication in which the high-temperature combustion gas is discharged, preheating and supplying hot water flowing into the hot water pipes has resulted in increasing the thermal efficiency of the entire system.

Claims (8)

In a general heating system comprising a heat exchanger block (1), a heating pipe (2), a hot water pipe (3), a circulation pump (4, 4 '), etc., including a burner, The heat exchanger block 1 is formed by being divided into a heating heat exchanger block 11 for inlet and an outlet to pass the heating fluid and a main water heat exchanger block 12 for passing hot water, The flow path 112 of the heating heat exchanger block 11 is formed in a zigzag form to have a predetermined width and depth, The flow passage 122 of the main hot water heat exchanger block 12 is formed in a zigzag shape to have a predetermined width and depth. The heating heat exchanger block (11) and the hot water heat exchanger block (12) is a fuel-saving heating system, characterized in that made by mutual coupling by a coupling member (19). The method of claim 1, Portions other than the flow paths 112 and 122 of the heating heat exchanger block 11 and the hot water heat exchanger block 12 are respectively contacted or passed through the hot gas or flame supplied from the combustion burner 16. Fuel-saving heating system, characterized in that the space portion (111, 121) is formed in the same size as the width of the heating heat exchanger block (11) and the flow path (112, 122) of the main hot water heat exchanger block (12). The method of claim 1, Oil flows through the flow path (112) of the heating heat exchanger block (11), and water flows through the flow path (122) of the hot water heat exchanger block (12). The method of claim 1, In order to heat the fluid and water flowing in the flow paths 112 and 122 of the heat exchanger block 1, at least one burner 16 is installed at the front portion of the heat exchanger block 1. Fuel-saving heating system characterized by. The method of claim 1, An exhaust heat exchanger for preheating the water supplied to the hot water heat exchanger block 12 by collecting heat of the combustion gas at the distal end of the communication 15 through which the high temperature combustion gas is discharged through the heat exchanger block 1. Fuel saving heating system, characterized in that further comprises 9). The method according to any one of claims 1 to 3, In order to allow a large amount of hot water to be heated in the main hot water heat exchanger block 12 attached to the heating heat exchanger block 11, the main hot water heat exchanger block 12 has the same width and depth, and a separate flow path is formed. Fuel-saving heating system that can be installed by adding at least one auxiliary hot water heat exchanger block (13). The method of claim 1, The straight pipe 21 of the heating pipe 2 has a heat radiation pipe 212 of a circular section larger than the diameter of the heating water pipe 211 around the heating water pipe 211 of the circular cross section in order to increase the heat transfer area after The heat dissipation tube 212 is compressed to contact the outer circumferential surface of the heating water pipe 211 to form an elliptical tube, In order to transfer the heat of the heating water pipe 211 to the heat dissipating pipe 212, at least one conductive plate 213 is attached to each other in the horizontal diameter direction of the heating water pipe 211 to form a straight pipe 21, In order to connect the straight pipes 21 arranged in a plurality of rows in series, the ends of the straight pipes 21 are screwed into the flexible connecting pipes 22 to form a heating pipe 2. Type heating system. The method of claim 7, wherein In order to position the straight pipe 21 easily at predetermined intervals and to transmit heat in one direction, a straight groove 2 having a predetermined depth is formed on the upper surface of the heat insulating material 5 to position the straight pipe 2. Fuel-saving heating system, characterized in that.